KR20070110492A - Glassware molds with cooling arrangement and method of cooling the glassware mold - Google Patents

Abstract

A mold for glassware forming machine includes a pair of mold segments (14) each having a central portion and laterally spaced edge portions (54) adapted to be brought together at the edge portions to form a mold cavity (16). A coolant shell (68) is externally mounted over the central poriton of each mold segment to form a cooling cavity (58) between the coolant shell and the central portion of the mold segment, and the coolant shells do not extend into the edge portion of the mold segments. Coolant passages (60) separate from the cooling cavities extend axially through the edge portions of the mold segments to facilitate cooling the edge portion in use.

Description

Glass Molds with Cooling Facility and Glass Molds Cooling Method {GLASSWARE MOLDS WITH COOLING ARRANGEMENT AND METHOD OF COOLING THE GLASSWARE MOLD}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to glassware molded products, and more particularly to cooling equipment for glassware molded molds.

Each section (IS) glassware forming apparatus typically includes one or more molds, each of which has a removable mold portion, thus providing a number of mold cavities aligned side-to-side. It is known to provide a cooling channel around the outside of the mold cavity in which air is detected to facilitate cooling of the mold. The mold section includes ribs extending radially and axially and extending into the cooling channel, and a cell surrounding the ribs; The cell surrounds the entire outer circumference of the mold section to form a cooling channel between the cell and the mold section. However, the space between adjacent mold cavities is limited, and the size of the mold section increases with the cooling channels disposed around it, so that the size of the glassware that can be molded in a given mold layout or IS device is limited.

The mold for the glass forming apparatus includes a pair of mold segments; This segment includes a central portion and laterally spaced edge portions that move from each other at the edge portion to form a mold cavity. A coolant shell is mounted outward above the center of each mold segment to form a cooling cavity between the center of the mold segment and the coolant cell, which does not extend to the edge of the mold segment. The coolant passage, separate from the cooling cavity, extends axially through the edge of the mold segment to facilitate cooling of the edge in use.

In one preferred embodiment, coolant passages are formed on both sides of the dividing line of the mold cavity formed by the mold segment. The coolant passage helps to cool the mold in the region of the dividing line, where proper cooling is not achieved by the air flow through the cooling cavity spaced from the region of the dividing line. Thus, the coolant passageway and the coolant cavity can improve product quality and robustness by providing uniform cooling of the mold in use.

Other objects, features and advantages of the present invention will be more clearly understood by the following detailed description with reference to the accompanying drawings.

1 is a perspective view of a portion of a mold assembly according to one preferred embodiment of the present invention, showing one mold segment carried by the base assembly;

2 is a rear view of the cover plate of the base assembly on which the mold segments are mounted.

3 is a cross-sectional view taken along line 3-3 of FIG.

4 is a sectional view along line 4-4 of FIG.

5 is a plan view of the mold;

1 and 5 illustrate a mold segment constructed in accordance with a preferred embodiment of the present invention and mounted to base assembly 12 for use in an IS glass forming apparatus (not shown). Although the illustrated base assembly 12 is configured to accommodate three mold segments, more base assemblies may be shown since only one is shown mounted in the figure. In use, two base assemblies 12 are provided in the IS device, each of which has three mounted mold segments 14.

Since the base assembly 12 and the mold segments take on complementary shapes, three mold cavities are formed when they are joined together, with one cavity between each three pairs of joined mold segments 14. Each mold segment 14 is preferably part of a mold assembly 10 that includes a cooling system for cooling the mold segment 14 in use. The mold is initially a blank mold or blow mold used to form a glass mass into a glass blank, which glass blank is transferred to a blow mold for molding into a glass article, such as a glass container, as is known in the art.

The base assembly 12 includes a base plate 20 having a bottom wall 22 and a peripheral side wall 24, which side wall is upwardly from the bottom wall 22 to form part of the chamber 26. Extends. Base plate 20 has a plurality of concave pockets 28 adjacent to each other to form mold segment receptacle 30. The receptacles 30 are partially separated from each other along their edges by the fingers 32. The finger 32 has an end face 34 arranged to contact the finger 32 on another base assembly when the mold segments 14 come close to each other to form a mold cavity therebetween. Chamber 26 extends into fingers 32.

The base assembly 12 has a cover plate 36 disposed on the base plate 20 that lies on the side wall 24 and surrounds and forms a portion of the chamber 26. The cover plate 36 has at least one, preferably a pair of inlet openings 38 arranged to communicate with an air chamber or plenum 40 (FIG. 4), thereby allowing air flow into the chamber 26. Provide passage for The plenum 40 is preferably in communication with a separate air compressor or a source of compressed air, such as compressed air lines in a plant, as is known. The cover plate 36 has at least one, preferably a pair of central outlet openings 42 for each mold segment on the base assembly 12. Since the opening 42 extends through the cover plate, it is opened to the chamber 26 to communicate the chamber 26 with the mold segment 14 mounted to the base assembly 12. In addition, a portion of the cover plate 36 overlying the finger 32 may be provided with at least one outlet opening provided as a slot 44 without limitation by way of example only for further communication between the chamber 26 and the mold segment 14. Have Adjacent to each receptacle 30 two slots 44 are provided, one slot 44 adjacent the finger 32 at each side of each receptacle 30. In this manner, the slot is adjacent to the end face 34 and generally adjacent to the dividing line in the mold cavity formed by the mold segment 14.

The mold segment 14 has a lower portion 46 having a reduced diameter to be received inside the receptacle 30 of the base assembly 12, which extends outwardly received in the cover plate 36 in the assembly. Provide a support surface 47. As shown in detail in FIG. 1, each mold segment 14 has an inner mold face 48 and an outer face 50, which laterally rests on the fingers 32 of the base assembly 12. It has a central portion 52 extending between the edge portion 54 spaced apart. The edge portion 54 of each mold segment 14 combines the mold segments 14 (FIG. 5) to form a mold cavity 16 between the mold faces 48 of the joined mold segments 14. Has a corresponding end face 55 in contact with the end face of the. A plurality of fins or ribs 56 extending in the axial direction extend outwardly from the central portion 52 of each mold segment 14, at least partially forming a cooling cavity 58, such cooling The cavity comprises a plurality of cooling channels which are generally open or generally separated, which form a cooling cavity in the collected state. The rib 56 spans the center portion 52 but does not extend to the edge portion 54. As shown in FIG. 4, the cooling cavity or cavities 58 are aligned so as to communicate with the central outlet opening 42 in the cover plate 36 when the mold segment 14 is mounted to the base assembly 12. do. Each mold segment edge 54 comprises at least one, preferably a pair of coolant passages 60; These coolant passages are spaced or overlapped from adjacent cooling cavities 58 and extend axially. The coolant passage 60 is not in direct communication with the cooling cavity 58. The coolant passageway 60 is a perforated hole extending axially through the mold segment, and because its end is open but completely closed by the edge portion 54, the air is different from one end in each passage 60. Can flow to one end. Since the coolant passages 60 are well spaced apart from each other, the air flow through the passages 60 cools different portions of the mold segment 14. As shown in FIGS. 2 and 3, the coolant passageway 60 is arranged to communicate with the slot 44 in the cover plate 36 when the mold segment 14 is mounted to the base assembly 12.

As shown in FIG. 4, a separate cooling jacket assembly 62 is disposed around the center portion 52 of each mold segment 14. Each cooling jacket assembly 62 includes a coolant cell 68 and a cell holder 64. The cell holder 64 is conveyed by the base assembly 12, and the cell 68 is conveyed and disposed by press fitting into the channel or recess of the holder. The cell 68 overlies the rib 56 and forms part of the cooling cavity or channel 58. The cell holder 64 has a bottom surface 70 engaged with the cover plate 36 and includes an opening or slot 80 which is placed over the central outlet opening 42 and in communication with the chamber 26. Coolant cell 68 is disposed radially inward from outlet opening 42 and has at least one opening 72; This opening provides a flow path of coolant into the cooling channel 58 between the coolant cell 68 and the rib 56. The cell holder 64 and coolant cell 68 do not extend beyond the central portion 52 to the edge portion 54 of the mold segment 14, thereby minimizing the diameter of each mold assembly 10. Cell 68 and fin 56 do not span more than about 130 ° outside of mold segment 14. For example, cell 68 and fin 56 span between about 100 ° and 130 ° outside of the mold segment.

The sleeve 64 includes a lip 74 that extends outwardly to facilitate attachment of the outer portion 78 of the sleeve 64 to the hanger arm 76 of the glass forming apparatus. The hanger arm (76) partially forms a plenum (40); The plenum is in communication with the air source and directs the air through the inlet opening 38 of the cover plate 36 into the chamber 26 of the base assembly 12. The plenum 40, unlike the one shown, is merely an example and also, without limitation, aligns the plenum to the bottom of the base assembly (not shown) and provides compressed air to the bottom wall 22 or sidewall 24 of the base plate 20. By passing directly through the opening of the chamber 26, it may be communicated for coolant flow with the chamber 26.

In operation, a pair of opposing mold segments 14 may be formed between the mold cavities 14 between the mold segments 14 whose respective end faces 55 are joined to receive glass masses and form in the form of mold cavities 16. Move toward each other until combined to form 16). To improve cooling of the mold segment, coolant, such as air, flows through the plenum 40 into the chamber 26 and exits to the outlet 42 and slot 44 of the base assembly 12. From the outlet 42, air flows into the cooling cavity 58 through the slot 80 of the holder 64 and through the opening 72 of the cell 68. Air from the slot 44 flows through the coolant passage 60.

Edge portion 54 requires a very small lateral space to accommodate coolant passageway 60. In addition, because the cell 68 and the holder 64 do not extend around the edge portion 54, large mold segments and mold cavities are used in a given IS device, which can produce large glass products. have.

Those skilled in the art should recognize that the embodiments falling within the following claims are merely exemplary. For example, instead of using a single plenum to provide air flow through the associated cooling cavities and passages, separate to direct coolant through the coolant passages 60 and cooling cavities 58 of the segment 14. Plenum or air source and / or other fluid may be used. In addition, the cell 68 may be trapped between the mold segment 14 and the holder 64 or otherwise disposed adjacent to the mold segment 14 therebetween.

The present invention has been described with reference to the preferred embodiments, and is not limited thereto, and one of ordinary skill in the art should recognize that various modifications and changes can be made to the present invention without departing from the appended claims.

Claims (15)

In the mold for glassware forming apparatus, A pair of mold segments 14 each having a central portion and laterally spaced edge portions 54, A pair of coolant cells 68 disposed adjacent to an associated mold segment on the center portion of the mold segment to form a cooling cavity 58 between the center portion of the mold segment and the cell; A coolant passageway (60) separated from the cooling cavity extending axially through the mold segment at the edge of the mold segment, Wherein the mold segments are in contact with each other at the edge portion to form a mold cavity (16), wherein the cell and cooling cavity do not extend into the edge portion of the mold segment. 2. The mold as claimed in claim 1, wherein the central portion comprises radially outwardly extending ribs extending axially along at least a portion of the central portion to partially form the cooling cavity. The mold according to claim 2, wherein the rib is not formed at the edge portion. The mold according to claim 1, wherein each cell (68) does not span more than 130 ° of the perimeter of the associated mold segment. The mold according to claim 1, wherein each cooling cavity (58) extends between 100 ° and 130 ° of the perimeter of the associated mold segment. The mold according to claim 1, wherein each cooling cavity (58) does not span more than 130 ° of the perimeter of the associated mold segment. The mold of claim 1, wherein each cooling cavity extends between 100 ° and 130 ° around an associated mold segment circumference. The mold according to claim 1, wherein each edge portion has an end face (55) that engages with the end face of the joined mold segment, and each coolant passageway (60) is adjacent to the end face. 10. The mold according to claim 8, wherein each coolant passageway (60) is inwardly spaced from an adjacent end face (55) and is not open to this end face. The mold of claim 1 wherein each edge portion (54) has at least one coolant passageway. In the mold for glassware forming apparatus, A pair of mold segments 14 each having a central portion and laterally spaced edge portions 54, A pair of coolant cells 68 each mounted to an associated mold segment above the center portion of the mold segment to form a cooling cavity 58 between the center portion of the mold segment and the cell, A coolant passage 60 extending axially through the mold segment and separated from the cooling cavity, The mold segments are in contact with each other at the edge portion to form a mold cavity (16); The cell and cooling cavity do not extend beyond about 130 ° of the mold segment circumference and do not extend to the edge of the mold segment; Wherein said at least one cooling passage is formed at each edge of the mold segment. 12. The mold of claim 11 wherein the coolant passageway is surrounded by an edge portion. A pair of mold segments 14 each having a laterally spaced edge portion 54 having at least one coolant passageway 60 at its central and edge portions forming part of the cooling cavity 58, In a method of cooling a glass mold, the mold segments are moved from one edge to another to form a mold cavity (16). Providing coolant to a cooling cavity relative to the central portion; Providing a coolant in a coolant passage to cool the edge portion. 14. A mold according to claim 13, wherein each mold segment further comprises a coolant cell (68) disposed over the center portion of the mold segment to form part of the cooling cavity between the center portion of the mold segment and the cell; Providing a coolant in the cooling cavity comprises directing air between the central portion and the cell. 14. The glass article mold of claim 13, wherein the coolant passageway (60) extends through the mold segment, wherein providing coolant to the coolant passageway includes moving air through the coolant passageway. Cooling method.

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